Quantum Transport through a DNA Wire in a Dissipative Environment

Gutiérrez, Rafael; Mandal, Sushil Kumar; Cuniberti, Gianaurelio

doi:10.1021/nl050623g

Cited by 74 publications

(74 citation statements)

References 28 publications

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“…On the other hand, using a combination of molecular mechanics (for conformation ensemble generation) and quantum mechanics (for electronic structure calculation), Starikov et al [52] have shown that molecular motion and mismatches can actually increase the conductance under certain conditions and provide more coupled electronic states. In yet another work [53] , quantum-mechanical simulations on a simple DNA model in contact with a heat bath showed significant electronic structure modulation, which could be useful in describing observed Ohmic behaviour in short DNA wires using a tunnelling approach. More recently, a complete ab-initio study using the nonequilibrium Green's function approach, was carried out by Song, et al [54] , to study the effects of the correlated stretching/twisting of a (GC) dimer.…”

Section: Environmental Conditions and Molecular Conformationmentioning

confidence: 95%

“…Usually, tight-binding Hamiltonians are employed to describe electronic structures of DNA duplexes -both explicitly (in the form of the "fishbone", "ladder" and similar models -see, for example, [51,53,58,60,[64][65][66][67][68][69][70][71][72] and the pertinent review articles [3,[73][74][75][76][77] ) and implicitly (within the framework of Marcus-type theories of charge transfer, for example, [55,[78][79][80][81] and the references therein). These works were successful in qualitatively (and sometimes even quantitatively) describing numerous experimental data (see, for example, [42,56,57,82,83] and the references therein) on transfer of injected single holes (or injected single electrons) through DNA duplexes.…”

Section: Critical Assessment Of the Biopolymer Charge Transfer/transpmentioning

confidence: 99%

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Electrical Conductance in Biological Molecules

Shinwari

Deen

Starikov

et al. 2010

Adv Funct Materials

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Nucleic acids and proteins are not only biologically important polymers: They have recently been recognized as novel functional materials surpassing in many aspects the conventional ones. Although Herculean efforts have been undertaken to unravel fine functioning mechanisms of the biopolymers in question, there is still much more to be done. This particular paper presents the topic of biomolecular charge transport, with a particular focus on charge transfer/transport in DNA and protein molecules. Here the experimentally revealed details, as well as the presently available theories, of charge transfer/transport along these biopolymers are critically reviewed and analyzed. A summary of the active research in this field is also given, along with a number of practical recommendations.)Received: ((will be filled in by the editorial staff))Revised: ((will be filled in by the editorial staff))

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Section: Environmental Conditions and Molecular Conformationmentioning

confidence: 95%

Section: Critical Assessment Of the Biopolymer Charge Transfer/transpmentioning

confidence: 99%

Electrical Conductance in Biological Molecules

Shinwari

Deen

Starikov

et al. 2010

Adv Funct Materials

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“…Finally, transport in bio-molecules attracted more attention, in particular electrical conductance of DNA [286,287,288,289,290].…”

Section: Atomistic Transport Theorymentioning

confidence: 99%

“…For equilibrium problems, unitary transformations combined with variational approaches can be used, in non-equilibrium only recently some attempts were made to deal with the problem. [139] In this section we will consider the case of a multi-level electronic system in interaction with a bosonic bath [288,289]. We will use unitary transformation techniques to deal with the problem, but will only focus on the low-bias transport, so that strong non-equilibrium effects can be disregarded.…”

Section: 1 the Model Hamiltonianmentioning

confidence: 99%

Green Function Techniques in the Treatment of Quantum Transport at the Molecular Scale

Ryndyk

Gutiérrez²,

Song

2009

Springer Series in Chemical Physics

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The theoretical investigation of charge (and spin) transport at nanometer length scales requires the use of advanced and powerful techniques able to deal with the dynamical properties of the relevant physical systems, to explicitly include out-of-equilibrium situations typical for electrical/heat transport as well as to take into account interaction effects in a systematic way. Equilibrium Green function techniques and their extension to non-equilibrium situations via the Keldysh formalism build one of the pillars of current state-of-the-art approaches to quantum transport which have been implemented in both model Hamiltonian formulations and first-principle methodologies. In this chapter we offer a tutorial overview of the applications of Green functions to deal with some fundamental aspects of charge transport at the nanoscale, mainly focusing on applications to model Hamiltonian formulations.

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“…We put forward new experimental setups to reveal the predicted effect and discuss possible applications of the DNA. In particular, we propose a design of the single molecule analog of the Esaki diode.Two approaches are widely used to describe the DNA: ab initio calculations [21][22][23][24][25][26][27][28] and model-based Hamiltonians [29][30][31][32][33][34][35][36][37][38][39][40][41][42][43][44]. The former can provide a detailed description but is currently limited to relatively short molecules (typically of the order of 10 base pairs long).…”

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confidence: 99%

DNA Double Helices for Single Molecule Electronics

Малышев

2007

Phys. Rev. Lett.

101

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The combination of self-assembly and electronic properties as well as its true nanoscale dimensions make DNA a promising candidate for a building block of single molecule electronics. We argue that the intrinsic double helix conformation of the DNA strands provides a possibility to drive the electric current through the DNA by the perpendicular electric (gating) field. The transistor effect in the poly(G)-poly(C) synthetic DNA is demonstrated within a simple model approach. We put forward experimental setups to observe the predicted effect and discuss possible device applications of DNA. In particular, we propose a design of the single molecule analog of the Esaki diode. DOI: 10.1103/PhysRevLett.98.096801 PACS numbers: 85.35.ÿp, 85.30.Mn, 85.30.Tv, 87.14.Gg The controversial question of charge transport in DNA molecules has been attracting a great deal of attention recently (see for an overview). The interest in DNA transport properties is at least twofold: on the one hand, the charge migration is believed to be important for the radiation damage repair [4] and, on the other, DNA double helices are expected to be particularly useful for molecular electronics [3,[5][6][7]. While random base sequences are relevant for biological samples, artificially created periodic DNA molecules [8], such as the poly(A)-poly(T) or poly(G)-poly(C), are probably the best candidates for novel device applications. The electrical transport through dry and wet DNA has been extensively studied both theoretically and experimentally and a variety of results has emerged: DNA has been reported to demonstrate proximity-induced superconducting [9], metallic [10 -13], semiconducting [14 -18], and insulating [19,20] behavior. Contact related effects, the impact of the environment, and the DNA base pair sequence lead to such diversity of results. According to both theory and experiment, the dry poly(G)-poly(C) synthetic DNA is a semiconductor: theoretical ab initio calculations predict a wide-band-gap semiconductor behavior (see, e.g., Ref.[21]) while experimental measurements reveal about 2 V voltage gap at low temperature [14].Many effects useful for molecular device applications have been reported: rectification, the Kondo effect, the Coulomb blockade, etc. (see Ref.[7] for a recent overview). In this contribution, it is demonstrated for the first time that the intrinsic helix conformation of the DNA strands determines the transport properties of gated DNA molecules. In particular, we show that the electric current through the double helix DNA (in the base stacking direction) can be driven by the perpendicular gating field. We put forward new experimental setups to reveal the predicted effect and discuss possible applications of the DNA. In particular, we propose a design of the single molecule analog of the Esaki diode.Two approaches are widely used to describe the DNA: ab initio calculations [21][22][23][24][25][26][27][28] and model-based Hamiltonians [29][30][31][32][33][34][35][36][37][38][39][40][41][42][43][44]. The former can pr...

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Quantum Transport through a DNA Wire in a Dissipative Environment

Cited by 74 publications

References 28 publications

Electrical Conductance in Biological Molecules

Electrical Conductance in Biological Molecules

Green Function Techniques in the Treatment of Quantum Transport at the Molecular Scale

DNA Double Helices for Single Molecule Electronics

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